Cellular Reproduction- Mitosis and
Cytokinesis
Eukaryotic Cell Reproduction
• Cell division includes mitosis
and cytokinesis.
• Mitosis it the division of the
nucleus.
• Cytokinesis is the division of
the cytoplasm.
• Daughter cells are genetically
identical.
2
Unicellular vs. Multicellular Mitosis
1. Unicellular organisms undergo
cell division to reproduce
themselves.
2. Multicellular organisms undergo
cell division for growth or repair,
or to make a new organism from
a fertilized egg,.
3
Purpose of Chromosomes
There are six feet of DNA in a
human somatic cell.
• DNA is wrapped around
histone proteins and coiled
forming chromosomes.
• Packaging DNA in
chromosomes prevents DNA
breakage and helps ensure
that each cell gets one copy of
each chromosome.
4
Coiling of DNA to Form Chromosomes
During interphase, the DNA forms chromatin. There
are areas of DNA that are tightly wound around
histones, and there are areas of DNA that are just
loosely wound around histones. This depends on the
DNA is being transcribed or replicated.
5
Coiling of DNA to Form Chromosomes
6
Chromatids Versus Chromosome
• Double stranded chromosomes are
held together by centromere.
• One half of a double stranded
chromosome is called a chromatid.
• The lengths of the chromatids may
also be held together by proteins
called cohesins.
7
Chromatids Versus Chromosome
8
Centromere vs. Kinetochore
9
Mitosis & Cell Division Animation
10
Prophase
•Chromatin fibers begin to
condense into chromosomes and
are visible under the microscope.
•Cohesins hold chromatid arms
together (vertebrates only at the
centromere).
•Nucleoli disappears.
•Mitotic spindle forms asters
radiating out from the centrosome.
•After replicating, the centrosomes
are moving to opposite poles.
11
Prophase
12
Prometaphase
Prometaphase
•Nuclear envelopes fragments and
nucleolus is no longer visible.
•Centrosomes are at opposite ends of the
nuclear area.
•The microtubules extend through the
nuclear area
•Two opposing kinetochores form on the
centromere on each chromatid.
•Kinetochore microtubules attach to the
kinetochores. Moving the chromosomes
back and forth until they reach the middle
of the cell.
13
Prometaphase
14
Prometaphase
15
Nonkinetochore Microtubules
Nonkinetochore microtubules overlap from opposite
poles.
16
Metaphase
Metaphase
• Longest phase of mitosis.
• Double stranded chromosomes line
up on the metaphase plate.
17
Metaphase
18
Anaphase
Anaphase•Cohesin proteins are cleaved and the
sister chromatids separate.
•The chromosomes are pulled to
opposite poles.
•The kinetochore microtubules are
disassembled at the chromosome
end.
•Spindle poles move apart by
interacting with nonkinetochore
microtubules.
19
Anaphase
20
Anaphase
21
Which End of the Microtubule is
Shortened?
Experiment
• During anaphase, mark the
microtubules to form a stripe.
• Observe which side of the
microtubules shorten.
• They shortened on the side of the
chromatids, so therefore the
kinetochores are disassembling the
kinetochores microtubules and not
the centrosome.
22
Telophase
• Two daughter nuclei form in the
cell.
• Nuclear envelope forms from the
fragments of the disassembled
nuclei and the endomembrane
system.
• Chromosomes unwind forming
chromatin.
• Beginning of cytokinesis
23
Telophase
24
Cytokinesis in Animals
•Mitosis without cytokinesis results in
multinucleated cells. This happens in
certain algae, plants, fungi, and even
a few animals.
•Animals cells do cytokinesis by the
pinching in of the cell membrane.
•Rings of actin form under the cell
membrane associated with myosin
contracts like a “pull-string” purse
forming a cleavage furrow.
25
Cytokinesis in Algae
In algal cells, cytokinesis occurs
by an inward growth of new cell
wall and membrane.
26
Cytokinesis in Higher Plants
In higher plants, cytokinesis begins in
the middle and proceeds toward the
periphery as membranous vesicles fuse
to form the cell plate..
27
Comparing Cytokinesis in Plants and Animals
28
Cytokinesis in Plants Versus Animals
29
Mitosis in a Plant Root Tip
Mitosis in a plant occurs in the root tips,
shoot tips and other specialized areas.
30
Overview of Mitosis
31